Surrogate modeling for spacecraft thermophysical models using deep learning

doi:10.1007/s00521-022-07257-7

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	Surrogate modeling for spacecraft thermophysical models using deep learning
	Y. Xiong; L. Guo; Y. Zhang; M. X. Xu; D. F. Tian and M. Li
	2022
发表期刊	Neural Computing & Applications
ISSN	0941-0643
卷号	34 期号:19 页码:16577-16603
摘要	Thermal modeling is a critical technology in spacecraft thermal control systems, where the complex spatially and temporally variable parameters used as inputs to the spacecraft usually result in long operation times, which hinders sensitivity analysis and control strategies. The uniqueness of both the space environment and the working conditions of each spacecraft, make thermal models differ in different space environments; thus, traditional thermal modeling methods that rely heavily on physical knowledge need to build more than one corresponding thermal model, and they also cannot generalize well. Therefore, an intelligent surrogate modeling strategy for spacecraft thermophysical models that uses deep learning, called SMS-DL, is proposed. An intelligent batch processing system for thermal analysis based on NX TMG Thermal Analysis was designed to automate the input of the thermal design parameters and the output of the thermal analysis results through macro-recording and playback using a state-of-the-art biconjugate gradient solver to provide superior speed, reliability, and accuracy, thus achieving a trade-off between high accuracy and low computational cost. One deep neural network based on Bayesian optimization was pre-trained using the thermal analysis data of the spacecraft in the source domain calculated using a batch processing system, which had a computational speed that was 1000+ times faster than that of the traditional thermophysical model and high computational accuracy of 99%+. Then, it was applied to the target domain with a limited amount of thermal analysis data using model fine-tuning. The theoretical and experimental results from the thermal analysis modeling of the near-ultraviolet radiation detector on the China Space Station Telescope developed in China demonstrated that deep transfer learning effectively adapted the pre-trained model from one working condition to another, improved the prediction accuracy by at least 86.4% over the direct prediction accuracy using the pre-trained model, and had better predictive performance than learning from scratch with only a limited amount of data.
DOI	10.1007/s00521-022-07257-7
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收录类别	sci ; ei
语种	英语
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文献类型	期刊论文
条目标识符	http://ir.ciomp.ac.cn/handle/181722/67138
专题	中国科学院长春光学精密机械与物理研究所
推荐引用方式 GB/T 7714	Y. Xiong,L. Guo,Y. Zhang,et al. Surrogate modeling for spacecraft thermophysical models using deep learning[J]. Neural Computing & Applications,2022,34(19):16577-16603.
APA	Y. Xiong,L. Guo,Y. Zhang,M. X. Xu,&D. F. Tian and M. Li.(2022).Surrogate modeling for spacecraft thermophysical models using deep learning.Neural Computing & Applications,34(19),16577-16603.
MLA	Y. Xiong,et al."Surrogate modeling for spacecraft thermophysical models using deep learning".Neural Computing & Applications 34.19(2022):16577-16603.

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